Doc/ref4.tex - platform/external/python/cpython3 - Gitiles

 \chapter{Execution model}
 \index{execution model}

 \section{Code blocks, execution frames, and name spaces} \label{execframes}
 \index{code block}
 \indexii{execution}{frame}
 \index{name space}

 A {\em code block} is a piece of Python program text that can be
 executed as a unit, such as a module, a class definition or a function
 body.  Some code blocks (like modules) are executed only once, others
 (like function bodies) may be executed many times.  Code blocks may
 textually contain other code blocks.  Code blocks may invoke other
 code blocks (that may or may not be textually contained in them) as
 part of their execution, e.g. by invoking (calling) a function.
 \index{code block}
 \indexii{code}{block}

 The following are code blocks:  A module is a code block.  A function
 body is a code block.  A class definition is a code block.  Each
 command typed interactively is a separate code block; a script file is
 a code block.  The string argument passed to the built-in function
 \verb@eval@ and to the \verb@exec@ statement are code blocks.
 And finally, the
 expression read and evaluated by the built-in function \verb@input@ is
 a code block.

 A code block is executed in an execution frame.  An {\em execution
 frame} contains some administrative information (used for debugging),
 determines where and how execution continues after the code block's
 execution has completed, and (perhaps most importantly) defines two
 name spaces, the local and the global name space, that affect
 execution of the code block.
 \indexii{execution}{frame}

 A {\em name space} is a mapping from names (identifiers) to objects.
 A particular name space may be referenced by more than one execution
 frame, and from other places as well.  Adding a name to a name space
 is called {\em binding} a name (to an object); changing the mapping of
 a name is called {\em rebinding}; removing a name is {\em unbinding}.
 Name spaces are functionally equivalent to dictionaries.
 \index{name space}
 \indexii{binding}{name}
 \indexii{rebinding}{name}
 \indexii{unbinding}{name}

 The {\em local name space} of an execution frame determines the default
 place where names are defined and searched.  The {\em global name
 space} determines the place where names listed in \verb@global@
 statements are defined and searched, and where names that are not
 explicitly bound in the current code block are searched.
 \indexii{local}{name space}
 \indexii{global}{name space}
 \stindex{global}

 Whether a name is local or global in a code block is determined by
 static inspection of the source text for the code block: in the
 absence of \verb@global@ statements, a name that is bound anywhere in
 the code block is local in the entire code block; all other names are
 considered global.  The \verb@global@ statement forces global
 interpretation of selected names throughout the code block.  The
 following constructs bind names: formal parameters, \verb@import@
 statements, class and function definitions (these bind the class or
 function name), and targets that are identifiers if occurring in an
 assignment, \verb@for@ loop header, or \verb@except@ clause header.

 A target occurring in a \verb@del@ statement is also considered bound
 for this purpose (though the actual semantics are to ``unbind'' the
 name).

 When a global name is not found in the global name space, it is
 searched in the list of ``built-in'' names (which is actually the
 global name space of the module \verb@__builtin__@).  When a name is not
 found at all, the \verb@NameError@ exception is raised.%
 \footnote{If the code block contains {\tt exec} statements or the
 construct {\tt from \ldots import *}, the semantics of names not
 explicitly mentioned in a {\tt global} statement change subtly: name
 lookup first searches the local name space, then the global one, then
 the built-in one.}
 \bimodindex{__builtin__}
 \stindex{from}
 \stindex{exec}
 \stindex{global}
 \ttindex{NameError}

 The following table lists the meaning of the local and global name
 space for various types of code blocks.  The name space for a
 particular module is automatically created when the module is first
 referenced.  Note that in almost all cases, the global name space is
 the name space of the containing module --- scopes in Python do not
 nest!

 \begin{center}
 \begin{tabular}{|l|l|l|l|}
 \hline
 Code block type & Global name space & Local name space & Notes \\
 \hline
 Module & n.s. for this module & same as global & \\
 Script & n.s. for \verb@__main__@ & same as global & \\
 Interactive command & n.s. for \verb@__main__@ & same as global & \\
 Class definition & global n.s. of containing block & new n.s. & \\
 Function body & global n.s. of containing block & new n.s. & \\
 String passed to \verb@exec@ statement
 	& global n.s. of cobtaining block
 		& local n.s. of containing block & (1) \\
 String passed to \verb@eval()@
 	& global n.s. of caller & local n.s. of caller & (1) \\
 File read by \verb@execfile()@
 	& global n.s. of caller & local n.s. of caller & (1) \\
 Expression read by \verb@input@
 	& global n.s. of caller & local n.s. of caller & \\
 \hline
 \end{tabular}
 \end{center}
 \bimodindex{__main__}

 Notes:

 \begin{description}

 \item[n.s.] means {\em name space}

 \item[(1)] The global and local name space for these can be
 overridden with optional extra arguments.

 \end{description}

 The built-in functions \verb@globals()@ and \verb@locals()@ returns a
 dictionary representing the current global and local name space,
 respectively.  The effect of modifications to this dictionary on the
 name space are undefined.%
 \footnote{The current implementations return the dictionary actually
 used to implement the name space, {\em except} for functions, where
 the optimizer may cause the local name space to be implemented
 differently, and \verb@locals()@ returns a read-only dictionary.}

 \section{Exceptions}

 Exceptions are a means of breaking out of the normal flow of control
 of a code block in order to handle errors or other exceptional
 conditions.  An exception is {\em raised} at the point where the error
 is detected; it may be {\em handled} by the surrounding code block or
 by any code block that directly or indirectly invoked the code block
 where the error occurred.
 \index{exception}
 \index{raise an exception}
 \index{handle an exception}
 \index{exception handler}
 \index{errors}
 \index{error handling}

 The Python interpreter raises an exception when it detects an run-time
 error (such as division by zero).  A Python program can also
 explicitly raise an exception with the \verb@raise@ statement.
 Exception handlers are specified with the \verb@try...except@
 statement.

 Python uses the ``termination'' model of error handling: an exception
 handler can find out what happened and continue execution at an outer
 level, but it cannot repair the cause of the error and retry the
 failing operation (except by re-entering the the offending piece of
 code from the top).

 When an exception is not handled at all, the interpreter terminates
 execution of the program, or returns to its interactive main loop.

 Exceptions are identified by string objects.  Two different string
 objects with the same value identify different exceptions.

 When an exception is raised, an object (maybe \verb@None@) is passed
 as the exception's ``parameter''; this object does not affect the
 selection of an exception handler, but is passed to the selected
 exception handler as additional information.

 See also the description of the \verb@try@ and \verb@raise@
 statements.
	\chapter{Execution model}
	\index{execution model}

	\section{Code blocks, execution frames, and name spaces} \label{execframes}
	\index{code block}
	\indexii{execution}{frame}
	\index{name space}

	A {\em code block} is a piece of Python program text that can be
	executed as a unit, such as a module, a class definition or a function
	body. Some code blocks (like modules) are executed only once, others
	(like function bodies) may be executed many times. Code blocks may
	textually contain other code blocks. Code blocks may invoke other
	code blocks (that may or may not be textually contained in them) as
	part of their execution, e.g. by invoking (calling) a function.
	\index{code block}
	\indexii{code}{block}

	The following are code blocks: A module is a code block. A function
	body is a code block. A class definition is a code block. Each
	command typed interactively is a separate code block; a script file is
	a code block. The string argument passed to the built-in function
	\verb@eval@ and to the \verb@exec@ statement are code blocks.
	And finally, the
	expression read and evaluated by the built-in function \verb@input@ is
	a code block.

	A code block is executed in an execution frame. An {\em execution
	frame} contains some administrative information (used for debugging),
	determines where and how execution continues after the code block's
	execution has completed, and (perhaps most importantly) defines two
	name spaces, the local and the global name space, that affect
	execution of the code block.
	\indexii{execution}{frame}

	A {\em name space} is a mapping from names (identifiers) to objects.
	A particular name space may be referenced by more than one execution
	frame, and from other places as well. Adding a name to a name space
	is called {\em binding} a name (to an object); changing the mapping of
	a name is called {\em rebinding}; removing a name is {\em unbinding}.
	Name spaces are functionally equivalent to dictionaries.
	\index{name space}
	\indexii{binding}{name}
	\indexii{rebinding}{name}
	\indexii{unbinding}{name}

	The {\em local name space} of an execution frame determines the default
	place where names are defined and searched. The {\em global name
	space} determines the place where names listed in \verb@global@
	statements are defined and searched, and where names that are not
	explicitly bound in the current code block are searched.
	\indexii{local}{name space}
	\indexii{global}{name space}
	\stindex{global}

	Whether a name is local or global in a code block is determined by
	static inspection of the source text for the code block: in the
	absence of \verb@global@ statements, a name that is bound anywhere in
	the code block is local in the entire code block; all other names are
	considered global. The \verb@global@ statement forces global
	interpretation of selected names throughout the code block. The
	following constructs bind names: formal parameters, \verb@import@
	statements, class and function definitions (these bind the class or
	function name), and targets that are identifiers if occurring in an
	assignment, \verb@for@ loop header, or \verb@except@ clause header.

	A target occurring in a \verb@del@ statement is also considered bound
	for this purpose (though the actual semantics are to ``unbind'' the
	name).

	When a global name is not found in the global name space, it is
	searched in the list of ``built-in'' names (which is actually the
	global name space of the module \verb@__builtin__@). When a name is not
	found at all, the \verb@NameError@ exception is raised.%
	\footnote{If the code block contains {\tt exec} statements or the
	construct {\tt from \ldots import *}, the semantics of names not
	explicitly mentioned in a {\tt global} statement change subtly: name
	lookup first searches the local name space, then the global one, then
	the built-in one.}
	\bimodindex{__builtin__}
	\stindex{from}
	\stindex{exec}
	\stindex{global}
	\ttindex{NameError}

	The following table lists the meaning of the local and global name
	space for various types of code blocks. The name space for a
	particular module is automatically created when the module is first
	referenced. Note that in almost all cases, the global name space is
	the name space of the containing module --- scopes in Python do not
	nest!

	\begin{center}
	\begin{tabular}{\|l\|l\|l\|l\|}
	\hline
	Code block type & Global name space & Local name space & Notes \\
	\hline
	Module & n.s. for this module & same as global & \\
	Script & n.s. for \verb@__main__@ & same as global & \\
	Interactive command & n.s. for \verb@__main__@ & same as global & \\
	Class definition & global n.s. of containing block & new n.s. & \\
	Function body & global n.s. of containing block & new n.s. & \\
	String passed to \verb@exec@ statement
	& global n.s. of cobtaining block
	& local n.s. of containing block & (1) \\
	String passed to \verb@eval()@
	& global n.s. of caller & local n.s. of caller & (1) \\
	File read by \verb@execfile()@
	& global n.s. of caller & local n.s. of caller & (1) \\
	Expression read by \verb@input@
	& global n.s. of caller & local n.s. of caller & \\
	\hline
	\end{tabular}
	\end{center}
	\bimodindex{__main__}

	Notes:

	\begin{description}

	\item[n.s.] means {\em name space}

	\item[(1)] The global and local name space for these can be
	overridden with optional extra arguments.

	\end{description}

	The built-in functions \verb@globals()@ and \verb@locals()@ returns a
	dictionary representing the current global and local name space,
	respectively. The effect of modifications to this dictionary on the
	name space are undefined.%
	\footnote{The current implementations return the dictionary actually
	used to implement the name space, {\em except} for functions, where
	the optimizer may cause the local name space to be implemented
	differently, and \verb@locals()@ returns a read-only dictionary.}

	\section{Exceptions}

	Exceptions are a means of breaking out of the normal flow of control
	of a code block in order to handle errors or other exceptional
	conditions. An exception is {\em raised} at the point where the error
	is detected; it may be {\em handled} by the surrounding code block or
	by any code block that directly or indirectly invoked the code block
	where the error occurred.
	\index{exception}
	\index{raise an exception}
	\index{handle an exception}
	\index{exception handler}
	\index{errors}
	\index{error handling}

	The Python interpreter raises an exception when it detects an run-time
	error (such as division by zero). A Python program can also
	explicitly raise an exception with the \verb@raise@ statement.
	Exception handlers are specified with the \verb@try...except@
	statement.

	Python uses the ``termination'' model of error handling: an exception
	handler can find out what happened and continue execution at an outer
	level, but it cannot repair the cause of the error and retry the
	failing operation (except by re-entering the the offending piece of
	code from the top).

	When an exception is not handled at all, the interpreter terminates
	execution of the program, or returns to its interactive main loop.

	Exceptions are identified by string objects. Two different string
	objects with the same value identify different exceptions.

	When an exception is raised, an object (maybe \verb@None@) is passed
	as the exception's ``parameter''; this object does not affect the
	selection of an exception handler, but is passed to the selected
	exception handler as additional information.

	See also the description of the \verb@try@ and \verb@raise@
	statements.